|Publication number||US3994341 A|
|Application number||US 05/627,306|
|Publication date||30 Nov 1976|
|Filing date||30 Oct 1975|
|Priority date||30 Oct 1975|
|Also published as||CA1060339A1, DE2649487A1, DE2649487C2|
|Publication number||05627306, 627306, US 3994341 A, US 3994341A, US-A-3994341, US3994341 A, US3994341A|
|Inventors||Donald J. Anderson, Charles F. Kirkvold, Peter Pisio, John R. Lishman|
|Original Assignee||Chevron Research Company|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (9), Referenced by (86), Classifications (8)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application is related to application Ser. No. 627,304, filed Oct. 30, 1975, for "Method of Recovering Viscous Petroleum from an Underground Formation," application Ser. No. 627,305, filed Oct. 30, 1975, for "Method of Recovering Viscous Petroleum from Tar Sand," application Ser. No. 643,579, filed Dec. 22, 1975, for "System for Recovering Viscous Petroleum from Thick Tar Sand," application Ser. No. 643,580, filed Dec. 22, 1975, for "Method of Recovering Viscous Petroleum from Thick Tar Sand," and application Ser. No. 650,571, filed Jan. 19, 1976, for "Arrangement for Recovering Viscous Petroleum from Thick Tar Sand".
This invention relates generally to recovering viscous petroleum from petroleum-containing formations. Throughout the world there are several major deposits of high-viscosity crude petroleum in oil sands not recoverable in their natural state through a well by ordinary production methods. In the United States, the major concentration of such deposits is in Utah, where approximately 26 billion barrels of in-place heavy oil or tar exists. In California, the estimate of in-place heavy oil or viscous crude is 220 million barrels. By far the largest deposits in the world are in the Province of Alberta, Canada, and represent a total in-place resource of almost 1000 billion barrels. The depths range from surface outcroppings to about 2000 feet.
To date, none of these deposits has been produced commercially by an in-situ technology. Only one commercial mining operation exists, and that is in a shallow Athabasca deposit. A second mining project is about 20% completed at the present time. However, there have been many in-situ well-to-well pilots, all of which used some form of thermal recovery after establishing communication between injector and producer. Normally such communication has been established by introducing a pancake fracture. The displacing or drive mechanism has been steam and combustion, such as the project at Gregoire Lake or steam and chemicals such as the early work on Lease 13 of the Athabasca deposit. Another means of developing communication is that proposed for the Peace River project. It is expected to develop well-to-well communication by injecting steam over a period of several years into an aquifer underlying the tar sand deposit at a depth of around 1800 feet. Probably the most active in-situ pilot in the oil sands has been that at Cold Lake. This project uses the huff-and-puff single-well method of steam stimulation and has been producing about 4000 barrels of viscous petroleum per day for several years from about 50 wells. This is probably a semi-commercial process, but whether it is a paying proposition is unknown.
The most difficult problem in any in-situ well-to-well viscous petroleum project is establishing and maintaining communication between injector and producer. In shallow deposits, fracturing to the surface has occurred in a number of pilots so that satisfactory drive pressure could not be maintained. In many cases, problems arise from healing of the fracture when the viscous petroleum that had been mobilized through heat cooled as it moved toward the producer. The cool petroleum is essentially immobile, since its viscosity in the Athabasca deposits, for example, is on the order of 100,000 to 1 million cp at reservoir temperature.
As noted, the major problem of the economic recovery from many formations has been establishing and maintaining communication between an injection position and a recovery position in the viscous oil-containing formation. This is primarily due to the character of the formations, where effective mobility of fluids may be extremely low, and in some cases, such as the Athabasca Tar Sands, virtually nil. Thus, the Athabasca Tar Sands, for example, are strip mined where the overburden is limited. In some tar sands, hydraulically fracturing has been used to establish communication between injectors and producers. This has not met with uniform success. A particularly difficult situation develops in the intermediate overburden depths, which cannot stand fracturing pressure.
Heretofore, many processes have been utilized in attempting to recover viscous petroleum from viscous oil formations of the Athabasca Tar Sands type. The application of heat to such viscous petroleum formations by steam or underground combustion has been attempted. The use of slotted liners positioned in the viscous oil formation as a conduit for hot fluids has also been suggested. However, these methods have not been overly successful because of the difficulty of establishing and maintaining communication between the injector and the producer. Clearly, if one could establish and maintain communication between injector and producer, regardless of the drive fluid or recovery technique employed, it would open up many of these viscous petroleum deposits to a number of potentially successful projects.
The present invention is directed to a method of assisting the recovery of viscous petroleum from a petroleum containing formation and is particularly useful in those formations where communication between an injection position and a recovery position is difficult to establish and maintain. The method in accordance with the present invention of assisting the recovery of viscous petroleum from a petroleum-containing formation is particularly useful in a formation having a large vertical dimension. A substantially vertical passage, such as a well or shaft, is formed through the petroleum-containing formation. A closed-loop flow path is provided from the earth's surface through a substantial portion of the formation penetrated by the vertical passage. A recovery path is formed for flowing petroleum out of the formation. This path may be located in the vertical passage near the bottom thereof or it may be located in a separate nearby well. A hot fluid is circulated through the closed-loop flow path to heat the viscous petroleum in the formation adjacent at least a portion of the vertical passage to form a potential passageway for fluid flow through the formation, and a drive fluid is injected into the upper portion of the formation through the potential passageway to promote flow of petroleum to the recovery position near the bottom of the vertical passage. In preferred form, the hot fluid which is flowed through the flow path is steam, and the drive fluid used to promote movement of the petroleum is also steam. In some situations, other fluids such as gas or water may be useful drive fluids. Depending on certain conditions, the hot fluid and the drive fluid are injected simultaneously. Under other conditions, the hot fluid and the drive fluid are injected intermittently or alternatively. The injectivity of the drive fluid into the formation is controlled to some extent by adjusting the flow of hot fluid through the flow path member. In this manner, the sweep efficiency of the drive fluid in the formation may be improved.
The principal object of the present invention is to maximize recovery of viscous petroleum from a tar sand having a large vertical dimension wherein communication between an injector position and a producer position is difficult to establish and maintain by utilizing a hot fluid in a physically separated, substantially vertical flow path through the formation to assist in establishing and maintaining communication for a drive fluid used to promote movement of the petroleum to the producer position. Further objects and advantages of the present invention will become apparent when the description is read in view of the accompanying drawings which are made a part of this specification.
FIG. 1 is an elevation view partially in section and illustrates the preferred embodiment of apparatus assembled in accordance with the present invention for use in recovering viscous petroleum from an underground formation;
FIG. 2 is an elevation view partially in section and illustrates an alternative arrangement of apparatus assembled in accordance with the present invention;
FIG. 3 is an enlarged partial view of a portion of the apparatus of FIG. 1;
FIG. 4 is a plan view and illustrates a potential well layout in accordance with the present invention;
FIG. 5 is an elevation view partially in section and illustrates apparatus used in conducting demonstrations in accordance with the present invention;
FIG. 6 is a perspective view of a block of tar sand flooded in accordance with the present invention showing position of core samples taken after the flood; and
FIG. 7 is a table illustrating the analysis of such cores.
Refer now to the drawings, and to FIG. 1 in particular, where the preferred embodiment of apparatus assembled in accordance with the invention is illustrated. FIG. 1 shows a substantially vertical passage formed through a petroleum-containing tar sand 14. The vertical passage may be a shaft or well, and for ease of description will be referred to herein as either. Thus, the shaft, generally indicated by the number 10, has been cased by means of casing 24. A wellhead 30 is located at the upper end of the casing 24. A hollow tubular member 18 extends through the wellhead 30 to a position near the lower part of the tar sand 14. An end plate 21 closes off the bottom of the tubular member. A flow pipe 20 extends down the interior of tubular member 18 and cooperates with the tubular member 18 to form a closed-loop flow path through at least a portion of the tar sand.
A source of hot fluid such as a steam source 32 is connected to flow pipe 20 by means of conduits 38 and 40 through valves 34 and 36. The steam source 32 is also connected to the interior of casing 24 by means of conduit 38 through valve 44. Steam is circulated through the formation out of direct contact therewith by flowing down flow pipe 20 and up the annulus between the outside of the flow pipe 20 and the tubular member 18. Fluid leaves this annulus via conduit 37 and valve 39. A production pump is located in the interior of the casing to move produced fluids to the surface via flow line 58.
The outside of tubular member 18 and the production flow line 58 are both packed off by packing means 41 to effectively form an upper injection chamber 43 and a lower production chamber 45 inside casing 24. Upper perforations 26 and lower perforations 27 are formed in the casing to permit communication between the interior of the casing and the formation. In operation, it is usually desirable to first introduce steam into the annulus 43 of the casing of shaft 10 to attempt to obtain injection of steam into formation 14 through perforations 26. In most instances, in viscous tar sands little or no injection is obtained. In accordance with the invention, steam is then flowed through a closed-loop flow path via flow pipe 20 and tubular member 18 by appropriate manipulation of valves 34, 36, 44 and 39. The steam or hot fluid flowing in the flow path formed of pipe 20 and tubular member 18 heats the viscous petroleum in tar sand formation 14 to reduce the viscosity of at least a portion of the petroleum adjacent the casing occupied by tubular member 18. This provides a potential passage for flow of the drive fluid or steam into the formation via annulus 43 and perforations 26. By suitably controlling the flow in the flow path 20, 18 and the formation 14, a good sweep efficiency can be obtained and oil recovery maximized through perforations 27 in recovery position 45. Thus when the steam flowing in the flow path establishes injectivity for the drive fluid into the formation and results in some production of petroleum from the producer steam flow through the flow path is terminated to prevent breakthrough of the drive fluid. If injectivity of the drive fluid becomes undesirably low, then additional steam is flowed through the flow path to reestablish the desired injectivity.
FIG. 2 is an elevation view partially in section, and illustrates an alternative embodiment of apparatus assembled in accordance with the present invention. As there shown, two closely spaced-apart wells 110 and 112 are formed and penetrate a tar sand formation 114. Well 110 includes a string of surface casing 124 which extends at least into the upper portion of the tar sand 114. The surface casing 124 is provided with a wellhead 130. A tubular member 118 extends through the wellhead and down through the tar sand. An inner flow pipe 120 cooperates with the tubular member 118 to form a closed-loop flow path for hot fluid through the formation. Thus, steam from steam source 132 is circulated through the flow path via conduit 140 and valve 136. Returning condensate through tubular member 118 may be removed via a crossover connection (not shown) for reheating and recirculating, if desired. The casing 124-tubular member 118 annulus is packed off by means of packing means 141. Steam may be injected into formation 114 from steam source 132 via conduit 138, valve 144 and perforations 126. A nearby production well 112 is provided with perforations 127 in the lower portion of the formation for recovery of petroleum moved there by the injected steam. A suitable pump 156 and flow line 158 are used to move it to the surface.
FIG. 4 is a plan view and illustrates a potential field layout. A central injector well 110 is surrounded by four producers 112N, 112E, 112S and 112W.
FIG. 5 is an elevation view partially in section and illustrates apparatus used in conducting demonstrations in accordance with the present invention. As there shown, a sand pack 70 of Athabasca tar sand was encased in a suitable elongated core tube 72. The core tube was provided with suitable end plates 74 and 76 for receiving a hollow tubular member 78. The apparatus is also arranged for steam injection into the face of the sand pack through conduit 80 and for collecting proceeds of the sand pack flood through conduit 82. A steam source 84 is connected to the tubular member 78 and to the sand pack face through tubing 86 and control valve 88. A down-stream control valve 90 controls flow of steam through the central tubular member 78. Thus, assisted recovery operations in accordance with the invention can be demonstrated utilizing the apparatus shown in FIG. 5.
FIG. 6 is a perspective of a block of Athabasca tar sand showing a number of core positions for cores taken longitudinally through the core block. The cores are identified by number and flow plane as indicated. The tar sand block was flooded in accordance with the method of the invention. The cores were taken after the flood and analyzed for residual petroleum. FIG. 7 is a table indicating the residual viscous petroleum weight by core position and plane of the cores of FIG. 6. The original block contained 13.5% by weight of viscous petroleum. As is evident from the table of FIG. 7, a substantial weight percent of a viscous petroleum was recovered when the cores were flooded in accordance with the method of the present invention.
Further with respect to FIGS. 5, 6 and 7, in order to demonstrate the method of the present invention, it was necessary as a first step to set up an apparatus containing Athabasca oil sand having a zero effective permeability to steam. To do this, a 1 inch-ID by 12 inches-long quartz tube was used. The tube was packed with Athabasca oil sand containing about 13% weight viscous petroleum and about 4% water. Fittings were attached to both ends of the tube and a conventional steam drive applied to the oil sand at a pressure of 75 psi and a temperature of 320° F. It was found during the early runs that 50% of the petroleum was recovered because of unrealistic permeability to steam, and so the runs did not successfully simulate Athabasca conditions. It was found later that by using a 1/2 inch-diameter solid steel rod, 12 inches long, as a tool for ramming the oil sand very tightly in the tube, the room temperature air permeabilities were reduced to less than 50 millidarcies, a much more realistic value for viscous petroleum-containing formations. In this region of permeability, conventional steam drive did not work and the steam front advanced only about 1 inch into the tube and no farther, since the initially mobilized petroleum blocked off any communication, thereby reducing the effective mobility to zero. These conditions were reproducible on a satisfactory basis.
The method of the invention was then demonstrated using the apparatus shown schematically in FIG. 5. FIG. 5 shows a partially completed demonstration in accordance with the method of the invention. The in-place tubular member 78 has been heated by opening the heating annulus control valve 90 allowing steam to pass through. This immediately provides steam injectivity at the drive end of the tar sand pack 70 and viscous petroleum produced immediately at the producing end. Recoveries in these experiments ranged from 48 to 52% weight of the total petroleum in place. Residual petroleum was determined in every case by exhaustive solvent extraction at the end of each run. In some demonstrations, too much heat was allowed to pass through the tubular member 78, thereby creating an annulus outside the tubular member of very high mobility, allowing premature steam breakthrough and giving rather poorer recoveries, on the order of only 30% of the total petroleum in place.
In order to demonstrate the present method in a laboratory under more realistic field-type conditions, the demonstrations were modified by using large chunks of relatively undistributed Athabasca oil sand. These ranged in weight from one to about four kilograms and appeared to be devoid of cracks. They were randomly shaped and generally roundish or oval. These were encased in epoxy resin so that a total thickness of about 4 inches existed all around the oil sand piece. The placement of the in-place tubular member and injector and producer were very similar to the apparatus shown in FIG. 5. Again, a 1/8 inch stainless-steel tube was used for the in-place tubular member. In order to establish that there was indeed zero effective mobility, a steam drive was always applied to the injector before allowing any heat to pass through the in-place tubular member. Three experiments were run, and in no case was there more than four drops of water produced at the exit from the block, and this slight water production ceased after less than one minute after initiating conventional steam drive. After reaching this static condition with zero injectivity, the heated annulus control valve 90 was cracked slightly, allowing passing of steam into the tubular member 78. Immediately petroleum flowed from the producer end of the core at a high petroleum/water ratio. Care must be exercised in controlling the amount of heat through the in-place tubular member since, in one case, this was not done and the over-all recovery was 30% of the total petroleum in place. Even continued flowing of steam through the block between injector and producer did not allow any further recovery of petroleum in this instance. On breaking open the block, it was found that a very clean oil sand of higher permeability had been created as an annulus close to the in-place pipe. Since the heat in the tubular member was not controlled, good sweep efficiency of the block was not obtained in this case.
The most successful demonstration run was that carried out on a 3.5-kg block of oil sand, initially 13.5% weight petroleum content. Total recovery was 65% of the petroleum originally in place. In all of these experiments, the same pressure and temperature of 75 psi and 320° F respectively were used.
Although, at first glance, the practice of the invention might lead one to expect a very low residual oil content close to the annulus surrounding the in-place tubular member and a high residual oil resulting from poor sweep efficiency in those regions of the sample farthest away from the in-place pipe, this was not the case. In fact, excellent sweep efficiency is obtained when the ratio of hot fluid to drive fluid is controlled so as not to permit early steam breakthrough. In order to evaluate this concern, the encased 3.5-kg block of oil sand at the end of a demonstration was cut through the center at right angles to the in-place tubular member. The oil sand was then cored using a 3/4 inch-diameter core borer and sampled to a depth of 1/2 inch. This was done at 11 locations in each of 6 different planes in the oil sand block. A diagram of the location of these core samples is shown in FIG. 6. A total of 66 samples was taken and each analyzed for residual petroleum content by exhaustive extraction with toluene. The results are shown in FIG. 7. It can be seen that a remarkably uniform sweep of the oil sand sample had taken place. Particularly surprising is the fact that the residual petroleum in those 6 cores taken from the annulus immediately surrounding the in-place tubular member show a residual petroleum content not too different from the cores farthest away from the in-place tubular member.
The demonstrations show that the method of the present invention satisfactorily simulated the zero effective mobility of the Athabasca oil sand deposit. The recovery demonstrations showed that a communication path between injector and producer can be successfully developed; and provided excessive heating of the in-place tubular member is avoided, recoveries up to 65% of the petroleum in place can be achieved. The sweep efficiency is surprisingly high, resulting in an even distribution of residual oil. This means that the reservoir after an assisted-recovery operation conducted in accordance with the invention would be amendable to further recovery techniques such as combustion, chemical floods, etc. Particularly attractive is the fact that injecting drive fluids would be confined to the area of interest between injector and producer, since this would be the only pathway open to them. In other words, it is unlikely that the fluids would be lost to the other parts of the reservoir because of the relative impermeability of the formation on the outer edge of the swept area.
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|U.S. Classification||166/272.3, 166/57|
|International Classification||E21B36/00, E21B43/24|
|Cooperative Classification||E21B36/00, E21B43/24|
|European Classification||E21B43/24, E21B36/00|